DE3629965A1 - Device for level measuring - Google Patents

Abstract

The invention concerns a device for measuring the level of vitrified high-activity wastes (HAW) in upright vessels. The device must be designed so that it makes it possible to determine the level of HAW or other inaccessible materials reliably, even in automatic or remote-controlled operation. This object is achieved by a) providing a detector system (3) with at least two gamma-ray detectors (9, 10), which b) are installed inside shielding (12, 13) in collimator apertures (14, 19; 15, 20) that can be aligned with the vessel (1), and which c) can be adjusted in their distance apart to defined positions with respect to the vertical extent (16) of the vessel (1). <IMAGE>

Description

The invention relates to a device for measuring the Level of glazed HAW in upright containers tern.

For the non-destructive measurement of the level of e.g. B. glazed HAW in molds offer measurements from / with Neutrons and / or gamma radiation. At the neutron measurement solution comes both an active (use of an external Source) as well as a passive measurement. Since the active measurement requires the use of an n-source but is not always available and the measurement effort is relatively expensive, this method is not preferred.

Analysis results on HAW have shown that the spontaneous cleavage of the Cm-244 alone results in a neutron emission per cm ³ LEWC and second of approx. 14-22 n / cm ³ sec. However, due to the use of hydrofluoric acid in the fuel and cladding tube solution, the LEWC contains up to 10 g fluorine / l. Fluorine goes quantitatively into the glass. The glass also contains 13% by weight boron (borosilicate glass). The neutron emission in the glass is thus mainly caused by neutrons from ( α , n) reactions on the elements fluorine and boron. The glass load with LEWC is approx. 1 l per 1 kg glass, corresponding to approx. 170 g oxide.

All of this ultimately results in a total neutron emission of more than 200 n / cm ³ sec in the glass. Based on experience with an n-detector with sensitivity ε = 1 cps / nv on the mold surface, this would result in a count rate of 500 cps.

Because a high spatial resolution is required for level determination would be (∼2 cm), a voluminous measurement setup would be required such. Laboratory tests showed that a PE shield  40 cm wall thickness is necessary to ensure a high Si gnal-underground ratio and so a drastic count to achieve an increase in ten. The passive n measurement can therefore also be excluded.

The underlying object of the invention is to make the EC device such that with it a reliable filling level determination of HAW or other inaccessible materials - is provided - even for automated or remotely controlled operation.

The solution is in the characteristic features of the claim ches 1 described.

The further claims give advantageous embodiments the invention again.

For measuring the level of the glazed HAW in Kokil len according to the invention the passive gamma measurement chooses. It is characterized by the simple structure and a high spatial resolution.

The detector system, consisting of e.g. B. 2 GM counter tubes with spherical lead shielding (radius 12 cm) as collimator, is mounted on a support plate and can be attached to the mold be brought into measuring position. In the horizontal plane is the distance between the 2 GM counter tubes, z. B. 15 cm (she lie symmetrically to the central axis), so that the inflowing Glass filament produces no significant signal increase and Position changes have no influence. The Höhenab stand of the detectors is also 15 cm, for example, so that the entire top half of the mold is monitored can. With lead filters in front of the collimator openings Gamma dose can be optimized at the detector location. For enough enough high specific activity of the glass (<Ci / l) with an additional collimator with a small slot height before the collimator opening, the spatial resolution is increased.  

The counting rate measured without a mold in the filling position increases with the filling of the mold to 1000 times so that there is a good signal / background ratio. The vertical movement of the mold allows the location resolution solution and positioning are optimized.

The gamma measuring system according to the invention allows a good loading attention to the filling process. With the lower measuring channel the upper half of the mold is monitored and malfunctions of the Filling process recognized early. With the upper measuring channel are the end of the filling process in normal operation fixed and the drying of the glass inflow observed.

From the comparison of the measurement data from the balance and the gamma measuring system calibration curves were obtained. Through the additional collimator the height to switch off the glass flow (= 175 kg) itself when the activity changes by a factor of 2 to 1.5 cm precisely defined.

In normal operation, the 3 values (scale, measuring channel below, Measuring channel above) match within the errors. vote the two values from the gamma measurement match and shows the If the balance deviates from this, there is a fault in front of the scales. The filling process can be carried out using the gamma Measurement can be ended safely. Since the gamma measuring system two has independent measuring channels, is an additional control le given.

The test measurements and testing during a larger one Period showed that the designed gamma measuring system reliably the fill level for switching off the glass inflow indicates and overfilling of the mold can be excluded can.  

For use in routine operation, a simplification is the Measuring electronics have been made. The details of the count rates (absolute) and the setting of the parameters for the micro processor are done by facilities (e.g. display, choice switch etc.) on the front panel and / or a printer Miniature keyboard is connected to the V24 interface, to make more extensive documentation.

Automatic calibration, which is particularly useful for the lower measuring channel, can be carried out by changing the program, taking the start signal into account, so that fluctuations in activity no longer play a role. This method takes advantage of the fact that the count rate ratio V = Z R ₁ / Z R _{2 of} the two measuring channels is independent of changes in activity. In the range between filling heights of 70 and 80 cm there is a significant dependency V = f (h).

The invention is explained in more detail below with reference to an exemplary embodiment using FIGS . 1-4.

The arrangement of the measuring device is shown in FIG. 1. In addition to the mold 1 towards the furnace cell 2 , the detector system 3 is mounted. The measuring electronics ( see also FIG. 3) are located outside the cell 5 next to the display of the scale 4 .

The structure of the device shows Fig. 1 as a vertical view and Fig. 2 as a horizontal view. The detector system 3 stands on a support plate 6 and can be brought to the mold 1 in the measuring position (shown) and pivoted out of the travel area of the mold carriage. By two support arm pairs 7 , 7 'with intermediate joint 8 , the detectors 9 , 10 can be moved in the direction of the mold center and thus the distance: detector mold can be varied without problems. The height change takes place via a spindle 11 .

The two detectors 9 and 10 - GM counter tubes - are embedded in lead balls 12 , 13 (shields) of 12 cm radius with a 4 cm long cylindrical intermediate part. This shape was chosen because it optimizes the weight of the shield. The recessed collimator slots 14 , 15 are made asymmetrically, so that the field of view 19 , 20 of the detectors 9 , 10 is sharply delimited downwards (vertical 16 ) and the beveling upwards allows a large viewing angle. The detectors 9 , 10 with a mutual distance of 15 cm in the horizontal plane see at 40 cm distance an area of Δ h = 11.5 cm and Δ b = 3.9 cm (mean geometric widths) and these fields of view 19 , 20 point past the center or the axis of symmetry (vertical 16 ) of the mold 1 (see FIG. 2). The inflowing glass thread thus produces no additional signals and changes in the positioning of the mold 1 do not cause any significant signal changes.

The height distance between the two detectors 9 , 10 is 15 cm. This setting was chosen so that the upper detector 9 sees the fill level for switching off the glass inflow in normal operation. With the lower detector 10 , the filling process (glass spout 22 , spout 23 ) is observed in the upper half of the mold. In the event of a malfunction, ie if the filling speed is too high up to 300 kg / h (= 3.2 cm / min), the filling process can be stopped early.

For higher specific activities of the glass (<Ci / l), the dose at the detector location is reduced by Pb filters 17 , 18 . Since the upper measuring channel 14 determines the height for switching off the glass flow, an additional collimator with a small slot height (6 mm) can be mounted there, and the spatial resolution can thus be significantly improved.

The gamma activity in glass 21 is approximately 1.9 TBq / l. The main emitter is ¹³⁷ Cs with approx. 1.4 TBq / l, whose gamma energy is 662 keV. Neglecting the gamma absorption in the glass 21 itself results in a dose at the detector location 9/10 of approx. 2.5 Siv for a spatial angle of 10-3 ster. This means that counting rates of approx. 500 cps can be achieved when using a miniature GM counter tube.

With a lead collimator that is 10 cm thick on all sides, you can almost achieve a step curve as a function of the fill level and thus a high spatial resolution. The detectors 9 , 10 see through the collimator slots 14 , 15 onto the edge region of the mold 1 (see FIG. 2).

An overview of the measuring electronics is shown in FIG. 3. Two GM counter tubes with the following sensitivities were installed as detectors 9 , 10 :

• 1. No. 132 ε = 103 400 cps / Siv (Cobalt 60),
• 2. No. 133 ε = 95 100 cps / Siv (Cobalt 60).

2.2 M were chosen as the resistance directly at the detector 9 or 10 .

The first module 24 , which was manufactured as a separate unit, includes the high voltage supply (550 V), the pre-amplifier and the discriminator (1.5 V).

At this block 24 , a control unit for United amplifier and discriminator setting with microprocessor 25 for limit value setting (current level 26 for the central computer 27 ; voltage level 28 for a recorder 29 ) and two counter inputs for count rates up to 5 kHz are statistically connected. The settings and the data query take place via a V24 interface 30 .

For the calibration operation of the measuring system, the discriminator signals 24 are given via a pulse shaper to a CAMAC scaler 31 which is controlled and read out by a desktop computer 32 (printer 33 ). For routine operation, the current signal between 4 and 20 mA is sufficient, which is controlled by a corresponding EPROM software and led to the central computer 27 .

The microprocessor 25 sums the pulses in a predetermined time period Δ t. These count rates ZR can be queried and documented via the V24 interface 30 .

The voltage signal 28 between 0 and 10 V and the Stromsi signal 26 between 4 and 20 mA are proportional to the count rate. The size of the signal can be changed by entering a scaling factor F via the V24 interface 30 .

The current signal 26 is fed to the central computer 27 . By comparing the weight information from the scale 4 ( FIG. 1) with the current values (the detectors 9 , 10 ), the calibration curves 34 and 35 according to FIG. 4 are obtained, which are entered in the form of reference points. On the screen in the control room, the 3 weights (scale, measuring channel below 10 , measuring channel above 9 ) can be compared. If the weight of 160 kg is displayed from the lower channel, a horn signal is given as a warning and if the weight of 170 kg is displayed from the upper channel, the warning signal is given to switch off the glass inflow 22 .

To protect the detectors 9 , 10 and easy data acquisition even for a possible increase in activity of the glass 21 by a factor of 2, lead filters 17 , 18 were placed in front of the collimator openings. The maximum count rate for the lower measuring channel ( 10 , 15 , 20 ) is 2000 cps and 1500 cps for the upper ( 19, 14, 19 ).

The weight of 5 kg at the beginning of filling corresponds to the contact pressure of the mold 1 on the outlet connection 23 . The difference between the filling weight and the display of the scale 4 at the end of the filling process indicates the increased contact pressure which arises as a result of the temperature increase due to the heating of the vessels.

At the beginning of the filling process, the count rate is very low. With increasing fill level, ie with increasing weight, more and more scattered radiation reaches detector 10 . The cha characteristic rise from 135 kg in the lower measuring channel means that the liquid level is seen by the detector 10 . After 160 kg the upper edge of the window is exceeded. The same course can also be observed for the upper measuring channel 9 . In this case, when the final weight is reached, the liquid level is still seen by the upper detector 9 . The comparison of the data shows a good reproducibility of the measurements.

If one takes the bandwidth of the scatter as a basis and assumes that the activity of the glass 21 does not change, the weighting can be determined from the counting rates in the range 135-155 kg for the lower measuring channel 10 and in the range 153-180 kg for the upper measuring channel 9 can be determined to within 2 kg. Outside the window, the count rate shows only a slight dependency on the weight, so that the accuracy deteriorates.

With the lower measuring channel 10 , the upper area of the mold 1 is observed and the upper measuring channel 9 can be used to switch off the filling process.

If the activity of the glass 21 changes , a new calibration curve ( FIG. 4) must be measured in order to obtain the correct assignment: counting rate weight.

The measurement time and the scaling factor are set via the V24 interface 30 ( FIG. 3). In order to achieve a high resolution of the current signal, the scaling factor is chosen so that the maximum count rate corresponds to a current of 16 mA. The safety distance of 20 mA is intended to prevent the microprocessor 25 from having to be readjusted in the event of minor activity changes. To protect the detectors 9 , 10 , the high voltage must be switched off after the mold 1 has been filled.

If a change in positioning of the detector 9 or 10 or additional changes z. B. Pb filter change vorgenom men and / or the measuring electronics is reset, a new calibration curve 34 or 35 (according. Fig. 4) must be included. The choice of support points should be selected according to the curvature of the curve, since a linear interpolation between the support points is carried out.

If the specific activity changes, a new calibration curve added.

In normal operation, the 3 values (scale, measuring channel below, Measuring channel above) match within the errors. Lies this agreement does not exist, the following cases are too differentiate:

• 1. The values from the gamma measurement agree with one another; together they show deviations with the scale 4 . If the values from the gamma measurements match in the range 120-170 kg, which allows a good weight determination from all 3 measuring channels, then there can only be an error on the scale 4 .
• 2. The value of the scale 4 only corresponds to a value of the gamma measurement. In this case there is a fault in the other measuring channel (detector 9 , 10 , measuring electronics, misalignment, changing the calibration, etc.).
• 3. The three values do not match. Case 2 may have occurred for both gamma measuring channels. An activity change has the same effect. When the activity is increased, both gamma values are above the values of scale 4 or vice versa.

In the event of large changes which supply a current signal I <19 mA which is too large or a current signal I _max <6 mA which is too small, the microprocessor 25 must be reset and / or the Pb filters 17, 18 must be replaced.

Claims (7)

1. Device for measuring the level of glazed HAW in upright containers, characterized by

• a) a detector system ( 3 ) with at least two gamma detectors ( 9 , 10 )
• b) are housed within shields ( 12 , 13 ) with collimator openings ( 14 , 19 ; 15 , 20 ) which can be aligned with the container ( 1 ) and the
• c) a distance from each other in defined positions with respect to the vertical extent ( 16 ) of the container ( 1 ) are adjustable.

2. Device according to claim 1, characterized in that the gamma detectors ( 9 , 10 ) with their shields ( 12 , 13 ) are arranged on a support arm ( 7 , 8 , 7 ') which is movable. 3. Device according to claim 1 and 2, characterized in that the two gamma detectors ( 9 , 10 ) in the Verti cal ( 16 ) are arranged at a distance from each other. 4. Device according to claim 1 or one of the following, characterized in that the collimator openings ( 14 , 19 ; 15 , 20 ) are aligned such that with the lower detector ( 10 ) the upper half of the container ( 1 ) concerning the level can be monitored and the end of the filling process can be determined with the upper detector ( 9 ). 5. Device according to claim 1 or one of the following, characterized in that filters ( 17 , 18 ) can be attached in front of the collimator openings ( 14 , 15 ). 6. Device according to claim 1 or one of the following, characterized in that the gamma detectors ( 9 , 10 ) by means of a toggle joint ( 7 , 8 , 7 ') are movable at least in the horizontal plane. 7. Device according to claim 1 or one of the following, characterized by an electronic circuit with Process control.